The present invention relates to a grip system and, in particular, golf club grips with a shaft attachment system for securing a replacement grip to a golf club shaft.
A wide variety of golf club grips are permitted by the relevant governing bodies for professional and amateur golf. Most golf clubs are provided by the manufacturer with a stock golf club grip already installed. These golf club grips are typically made of rubber or a synthetic material meant to simulate rubber. An outer wrap of leather or leather-like material can be implemented to add diameter to the grip and give it its basic profile.
Accordingly, there remains a continued need for an improved system for securing replacement grips onto golf club shafts, and in particular, replacement grips that can be quickly secured to a wide variety of tapered golf club shafts without requiring professional assistance.
A golf club grip may include a docking tube and an elongated handle. The docking tube may be configured to couple to a golf club shaft and may include a docking tube sidewall. The elongated handle may be detachably couplable to the docking tube. The elongated handle may include an elongated handle sidewall defining an axial opening configured to receive the docking tube. At least one of the docking tube sidewall and the elongated handle sidewall may include a projection, and the other of the docking tube sidewall and the elongated handle sidewall may include a channel. The channel may be configured to receive the projection to prevent rotation of the elongated handle relative to the docking tube when the elongated handle is coupled to the docking tube.
The docking tube may comprise a hollow structure configured to receive the golf club shaft. The projection may be one of a plurality of projections on the at least one of the docking tube sidewall and the elongated handle sidewall. The docking tube sidewall may include the plurality of projections, and an intermediate section of the docking tube sidewall may interconnect a first projection of the plurality of projections and a second projection of the plurality of projections. The intermediate section of the docking tube sidewall may define a radius of curvature greater than a radius of curvature defined by at least one of the plurality of projections.
In a further embodiment, the docking tube sidewall may include the projection and the docking tube may include a plurality of ribs extending at least partially along an exterior of the docking tube sidewall. The projection may be bordered by two ribs of the plurality of ribs. One rib of the plurality of ribs and the projection may have different cross-sectional shapes when viewed from a proximal end of the docking tube. The projection and two ribs of the plurality of ribs may be configured to be received in the channel when the elongated handle is coupled to the docking tube.
In a further embodiment, an insert may be received within an end portion of the docking tube. The insert may include a shank having external threads, a head that may be wider than the shank, and an internally threaded bore. A weighted insert may be threadedly engageable with the internally threaded bore of the insert. A ring insert may be positionable within an opening in an end of the elongated handle. The ring insert may include an engagement surface configured to engage a weighted end cap. The ring insert may include a chamfered annular surface opposite the engagement surface.
The elongated handle may include an underlisting and an outer gripping surface. The elongated handle may include a proximal end and a distal end with a portion of the docking tube extending distally beyond the distal end of the elongated handle when the elongated handle is coupled to the docking tube. A docking sleeve may surround the portion of the docking tube that extends distally beyond the distal end of the elongated handle.
The docking tube sidewall may define a generally circular cross-section when viewed from a proximal end of the elongated handle. The elongated handle may include the channel, and the channel may be one of a plurality of channels, the plurality of channels being disposed in a radially asymmetric arrangement about a centerline axis of the axial opening.
The projection may be one of a plurality of projections and each of the plurality of channels may be configured to receive a different one of the plurality of projections when the elongated handle is coupled to the docking tube. The docking tube sidewall may include the projection, and the projection may be outwardly convex.
A further embodiment may include an elongated handle for attachment to a docking tube having protrusions. The elongated handle may include an outer gripping surface and an underlisting. The underlisting may define an axial opening including an annular surface and a plurality of longitudinal channels. The plurality of longitudinal channels may be recessed relative to the annular surface and disposed about a centerline axis of the elongated handle. The plurality of longitudinal channels may be configured to receive the protrusions of the docking tube such that the elongated handle is prevented from rotating with respect to the docking tube about the centerline axis.
The plurality of longitudinal channels may have a generally rectangular cross-section when viewed from a proximal end of the elongated handle. The plurality of longitudinal channels may define a uniform width and a uniform depth. The uniform width may be greater than the uniform depth. The plurality of longitudinal channels may include five channels. The plurality of longitudinal channels may be disposed in a radially asymmetric arrangement about the centerline axis of the elongated handle such that the docking tube can be received in the axial opening in only a single orientation.
A butt end of the elongated handle may include a stepped opening, and the elongated handle may further include a ring insert that may be seated within the stepped opening in the butt end of the elongated handle. The ring insert may include a flat engagement surface to detachably receive a weighted end cap. The ring insert may include a chamfered annular surface opposite of the flat engagement surface.
A method of securing a golf club grip to a golf club may include positioning an elongated handle on a docking tube such that the docking tube is received in an axial opening of the elongated handle. The docking tube may be coupled to a golf club shaft. At least one of the docking tube and the elongated handle may include a projection and the other of the docking tube and the elongated handle may include a channel and positioning the elongated handle on the docking tube may include positioning the projection in the channel such that the elongated handle is rotationally fixed relative to the docking tube.
In a further embodiment, the method may include securing the docking tube to the golf club shaft, thereby rotationally fixing the docking tube to the golf club shaft.
The docking tube may be rotationally fixed relative to the golf club shaft and positioning the elongated handle on the docking tube includes rotationally fixing the elongated handle relative to the golf club shaft. Positioning the elongated handle on the docking tube may include moving the elongated handle relative to the docking tube from an initial position when the elongated handle first engages the docking tube to a final position. The elongated handle may be rotationally fixed relative to the docking tube as the elongated handle is moved from the initial position to the final position.
In a further embodiment, the method may include detaching the elongated handle from the docking tube and positioning a second elongated handle on the docking tube. The docking tube may remain secured to the golf club shaft while detaching the elongated handle from the docking tube.
An interchangeable golf club grip with a shaft attachment system is provided. In one embodiment, the shaft attachment system includes a docking tube positioned within an axial opening in the golf club grip. The docking tube includes multiple lengthwise projections, each being positioned within a corresponding channel in the golf club grip to prevent relative rotation between the golf club grip and the docking tube. When press-fit over a golf club shaft, the docking tube sidewall securely conforms to the outer diameter of the golf club shaft, despite the golf club shaft having an outer diameter that varies along all or a portion of its length.
In one embodiment, each lengthwise projection is a raised portion of the docking tube sidewall and is outwardly convex. Each lengthwise projection is optionally bordered by two longitudinal ribs that extend parallel to each other. In this embodiment, one lengthwise projection and two longitudinal ribs are received within a channel in an underlisting. Multiple channels may be disposed asymmetrically about the centerline axis of the underlisting, such that docking tube can be received in the axial opening of the golf club grip with only a single orientation.
In another embodiment, the docking tube includes a sidewall defining a polygonal cross-section, for example, a hexagonal cross-section or an octagonal cross-section. The longitudinal ribs are aligned with the corner portions of the polygonal cross-section, and the sidewall is outwardly concave between adjacent corners. The outwardly concave sidewall can flex outwardly when the docking tube is press-fit over the golf club shaft. The docking tube thereby provides an interference fit with the golf club shaft along its entire length.
In another embodiment, the docking tube includes an elongated channel defining an open cross-section. The elongated channel is tube-shaped except for a lengthwise gap that extends along the entirety of the length of the elongated channel. The elongated channel is formed from an elastically deformable material to flex radially outwardly and fit over a golf club shaft. The inner surface of the golf club grip and the outer surface of the elongated channel include inter-engaging surfaces that prevent relative rotation therebetween. The inner surface of the elongated channel is optionally coated with a friction material to resist rotation of the golf club shaft therein.
In still another embodiment, the shaft attachment system further includes a lower clamp assembly having a resilient skirt and a ring clamp. The resilient skirt is joined to the docking tube and extends from the axial opening in the golf club grip. The resilient skirt includes multiple flanges, each of the flanges including a friction surface. The ring clamp fits over the resilient skirt and includes multiple cams for engaging the flanges, such that rotation of the ring clamp relative to the resilient skirt biases the friction surface of each of the flanges inwardly to secure the golf club grip to the golf club shaft. Rotation of the ring clamp can be reversed to unlock the resilient skirt, without the use of hand tools, if removal of the golf club grip is desired.
In yet another embodiment, the lower clamp assembly includes a removable installation tool for a compression clamp as part of a lower clamp assembly. The removable installation tool includes an inverted U-shaped yoke extending partially around the compression clamp and a screw extending through the base of the yoke and oriented to engage a gap between spaced apart portions of the compression clamp. Rotation of the screw relative to the yoke causes the screw tip to lower into this gap, which in turn causes the compression clamp to expand. Once expanded, the compression clamp can be freely guided over the docking tube during installation of the golf club grip and during removal of the golf club grip. The compression clamp is therefore a binary clamping system that provides a non-adjustable clamping force during play.
The golf club grip is optionally a widened grip, in particular a replacement golf club grip for a putter. The golf club grip further optionally includes a generally rectangular cross-section with a central axis that generally coincides with the axis of the golf club shaft. The rectangular cross-section is sufficiently widened to permit a forward-facing surface of the golf club grip (in the heel-to-toe direction) to function as a point of engagement for left and right thumbs. The golf club grip is easily mounted and dismounted to a golf club shaft with minimal or no hand tools, thereby providing a customized grip that is held in position along the length of the golf club grip despite the golf club shaft having a tapered outer diameter.
These and other features and advantages of the present invention will become apparent from the following description of the invention, when viewed in accordance with the accompanying drawings and the appended claims.
The current embodiments generally relate to a replacement golf club grip having a shaft attachment system. The shaft attachment system includes one or more of the following features, alone or in combination, to secure a golf club grip to tapered and non-tapered golf club shafts: a docking tube, a lower clamp assembly, and an upper clamp assembly. While illustrated in connection with a widened putter grip, the shaft attachment system can also be used in connection with conventional grips for woods, irons, hybrids, and drivers, for example. The grip system may also be used in connection with other devices. For example, the grip system may be used with construction equipment (e.g., shovel, pick, axe, hammer, trowel, power tool) or athletic equipment for other sports (e.g., tennis, badminton, racquetball, squash).
A golf club grip 10 having a shaft attachment system in accordance with a first embodiment is illustrated in
The docking tube 12 comprises the innermost portion of the golf club grip 10 and generally includes a uniform cross-section along its entire length. The docking tube 12 includes an elastically deformable sidewall 22 defining a closed hollow structure, optionally having a polygonal cross-section. In other embodiments, the docking tube 12 defines an open structure (e.g., having a C-shaped cross-section). As shown in
The longitudinal ribs 24 are positioned within corresponding grooves 26 in the underlisting 18 to prevent relative rotation between the underlisting 18 and the docking tube 12. In an unstressed state, the portions of the sidewall 22 between the longitudinal ribs 24 (termed “intermediate portions” herein) include a reduced inner diameter as shown in
In the embodiment of
As further shown in
Referring again to
Referring to
As also shown in
The golf club grip 10 also includes a gripping surface 76 of any suitable material—including natural rubber, silicon rubber, or plastic, for example—generally having a lower durometer than the underlisting 18. The gripping surface 76 is a molded monolithic element in the current embodiment, optionally a molded EVA sleeve that extends over the underlisting 18. In some embodiments, the underlisting 18 provides a seating surface to which the softer gripping surface 76 is directly molded. In other embodiments, the underlisting 18 and the gripping surface 76 are integrally formed with one another and comprise a single element of an elongated outer handle for the golf club grip 10. As also shown in
The golf club grip 10 can be attached to a tapered shaft 20 in the following manner. The ring clamp 34 is loosely inserted over the shaft 20, and the shaft 20 is then press-fit into the docking tube 12. The docking tube sidewall 22 (at this point being glued to the interior of the golf club grip 10) engages the shaft 20 and flexes outwardly as the widest portion of the shaft 20 passes through the docking tube 12. Because the sidewall 22 is elastically deformable, it can accommodate various diameters, including the tapered outer diameter of the golf club shaft 20, which can vary by as much as 6 mm or more along the length of the golf club grip 10. The docking tube sidewall 22 conforms to the outer diameter of the golf club shaft 20, despite the golf club shaft 20 having an outer diameter that varies along its length. With the golf club grip 10 properly aligned, the ring clamp 34 is brought into engagement with the resilient skirt 32 and rotated clockwise until the cams 40 engage the flexible flanges 36, bringing the friction surfaces 38 into engagement with the golf club shaft 20. At the upper end of the golf club grip 10, the upper clamp assembly 16 is fully inserted into the guide cap 42. The bolt 44 is then rotated clockwise through a range of about 180 degrees to lock the upper clamp assembly 16 in place in the golf club grip 10. The foregoing steps can be repeated in the reverse order if replacement of the golf club grip 10 is desired, or if the same golf club grip 10 is desired for another golf club.
Referring to
As also shown in
The golf club grip 90 of
Referring now to
As shown in
Referring now to
As shown in
The installation tool 160 can be used to install the golf club grip 130 of
Removal of the golf club grip 130 is accomplished in the same manner. First, the installation tool 160 is lowered onto the golf club shaft 20 as shown in
Referring now to
The universal docking tube 202 remains affixed to the golf club shaft and can be used with a wide variety of handles 204, including handles for a round grip, a pistol grip, or a rectangular grip. The end cap assembly 206 centers the upper end of the docking tube 202 within the elongated handle 204, and the collar assembly 208 secures the lower end of the docking tube 202 to a golf club shaft. Each such feature is discussed below.
In some embodiments, the docking tube 202 defines a closed hollow structure. In other embodiments, the docking tube 202 defines an open structure (e.g., having a C-shaped cross-section). A docking tube 202 having a cross-sectional shape as shown in
The docking tube 202 is shown in
In some embodiments, the ribs are optional. Some embodiments, including the embodiment shown in
In some embodiments, the longitudinal ribs 210 extend the entire length or substantially the entire length of the docking tube 202. In other embodiments, the longitudinal ribs 210 extend along a portion of the length of the docking tube 202. In some embodiments, the longitudinal rib 210 is uninterrupted along its length. In other embodiments, the longitudinal rib 210 includes two or more segments spaced from each other along its length.
In some embodiments, the longitudinal ribs 210 extend along an axis generally parallel to a longitudinal axis of the docking tube 202. For example, the longitudinal ribs 210 may be coplanar with the longitudinal axis of the docking tube 202. In other embodiments, the longitudinal ribs 210 may be at an angle relative to the longitudinal axis of the docking tube 202 such that the elongated handle must be rotated when coupling the elongated handle to the docking tube 202. In some embodiments, the longitudinal ribs 210 define a thread that engages a thread on the underlisting or elongated handle.
As also shown in
Each lengthwise projection is connected to an adjacent lengthwise projection by an intermediate section 216 of the cylindrical sidewall 212. The intermediate section 216 define a radius of curvature that is greater than the radius of curvature defined by the lengthwise projections 214.
The lengthwise projection 214 may extend along a substantial portion of the length of the docking tube 202, optionally along the entire length of the docking tube 202 as shown in
In some embodiments, the lengthwise projection 214 extends along an axis generally parallel to a longitudinal axis of the docking tube 202. For example, the lengthwise projection 214 may be coplanar with the longitudinal axis of the docking tube 202. In other embodiments, the lengthwise projection 214 may be at an angle relative to the longitudinal axis of the docking tube 202 such that the elongated handle must be rotated when coupling the elongated handle to the docking tube 202. In some embodiments, the lengthwise projection 214 defines a thread that engages a thread on the underlisting or elongated handle. The lengthwise projection 214 may be generally parallel to one or more longitudinal ribs 210.
The elongated handle 204 includes an outer grip surface 218 and an underlisting 220. As shown in
Each channel 222 is shaped (e.g., rectangular or semi-circular) in cross-section to accept one or more ribs 210 (e.g., two laterally spaced ribs which may be parallel) and/or a lengthwise projection 214, best shown in
The lengthwise projections 214 of the docking tube 202 may have a sidewall thickness that is different from the sidewall thickness of the intermediate portion 216 such that the lengthwise projections 214 are resiliently flexible. The lengthwise projections 214 may be formed from a first material and another portion of the docking tube 202 may be formed from a second material that is different from the first material.
One or more of the docking tube 202, handle 204, and underlisting 220 may be manufactured from a material that is different than the material of the other of the docking tube 202, handle 204, and underlisting 220. The different materials may have different coefficients of thermal expansion. Referring to
In some embodiments, the docking tube 202 is formed from a thermoplastic, for example polyvinyl chloride (PVC), while in other embodiments the docking tube 202 is formed from a metal or metal alloy (e.g., aluminum or aluminum alloys, titanium or titanium alloys, steel, etc.). In some embodiments, forming docking tube 202 from a metallic material may allow docking tube 202 to have a thinner sidewall than embodiments formed from thermoplastic. In still other embodiments, at least a portion of the docking tube 202 is formed from steel or rubber. In some embodiments, docking tube 202 is made of metal (e.g., aluminum or steel). In other embodiments, docking tube 202 is made of a composite material (e.g., graphite composite or fiber reinforced polymer). A metal docking tube 202 may have a wall thickness from about 0.005″ to about 0.05″, for example, about 0.005″, about 0.01″, about 0.015″, about 0.03″, or less than about 0.05″. A composite docking tube 202 may have a wall thickness of about 0.02″, about 0.035″, about 0.05″, or less than about 0.075″. A metal docking tube may have a thinner sidewall than a composite docking tube. A metal docking tube may have a ratio of wall thickness to stiffness or rigidity compared to a composite docking tube. A metal docking tube may have tighter manufacturing tolerances than a composite docking tube. A metal docking tube may be corrosion resistant to water based solvents. The docking tube 202 may be manufactured by extrusion, die casting, or milling. In some embodiments, docking tube 202 may be produced by an additive manufacturing process (e.g., 3D printing). Docking tube 202 may include an anodized or plated surface. An anodized or plated surface may reduce or minimize frictional forces when assembling high friction materials like rubber or other elastomeric sleeves onto the docking tube.
Elongated handle 204 may be made of a lightweight and/or elastic material. In some embodiments, elongated handle is made of a polymeric material (e.g., ethylene-vinyl acetate (“EVA”), EVA coated with polyurethane, foam rubber, polypropylene foam, polyethylene foam, rubber, or oxygenated thermoplastic). Elongated handle may have a hardness of 80 Shore A or softer. A softer grip may provide a better feel for the user than a harder grip during use of the handle. A polymeric handle may be elongated to overcome interference fit features of the docking tube. Elongated handle may be made of a material with a closed cell design. A closed cell design may prevent water absorption. A closed cell design may provide resistance to oxygen, ozone, and light.
In some embodiments, docking tube 202 is made of metal and elongated handle is made of polymer. In other embodiments, docking tube 202 is made of polymer and elongated handle 204 is made of metal. In still other embodiments, docking tube 202 and handle 204 are each made of polymer or composite. In some embodiments, a ratio of the weight of the grip to the torsional resistance is about 0.1 to about 2.0, about 0.75 to about 1.5, about 0.5 to about 1.0, or less than about 1.0. In other embodiments, a ratio of the weight of the grip to the torsional resistance is about 10 to about 40, about 15 to about 30, or about 20 to about 25. In some embodiments, a ratio of the weight of the grip to the torsional resistance of a docking tube (e.g., a metal docking tube) and an underlisting (e.g., plastic, composite, or EVA) is about 0.5 to about 1.0 or less than about 1.0. In some embodiments, a ratio of the weight of the grip to the torsional resistance of a docking tube (e.g., a plastic docking tube) and an underlisting (e.g., plastic, composite, or EVA) is about 20 to about 24.
The rib 210 and lengthwise projection 214 may extend radially outwardly away from the sidewall of the docking tube 202. In some embodiments, the channel 222 may receive at least one of rib 210 and lengthwise projection 214. The rib 210 or lengthwise projection 214 may extend radially outwardly such that an end of the rib 210 or lengthwise projection 214 contacts an endwall 215 of the channel 222. The end of the rib 210 or lengthwise projection 214 may contact the endwall 215 of the channel 222 while the portion of the sidewall 212 between the rib 210 and lengthwise projection 214 may be radially spaced from the endwall 215 of the channel 222. The rib 210 may contact the endwall 215 of the channel 222 and the lengthwise projection 214 may be radially spaced from the endwall 215. The rib 210 may be compressed radially by the endwall 215. In some embodiments, the rib 210 is compressed by the sidewall of the channel 222. In other embodiments, the sidewall of the channel 222 is compressed by the rib 210.
In some embodiments, the docking tube 202 includes the lengthwise projections 214 and the ribs 210 and the elongated handle 204 includes the channel 222. In other embodiments, the elongated handle 204 includes the lengthwise projections 214 and the ribs 210 and the docking tube 202 includes the channel 222. In still other embodiments, the docking tube 202 and elongated handle 204 each include a combination of lengthwise projections 214, ribs 210 and channels 222. The channel 222, ribs 210, or projections 214 may extend the length of the handle 204 or docking tube 202 such that the handle 204 is rotationally fixed relative to the docking tube 202 and shaft as the handle is being coupled to the docking tube. For example, the handle 204 may be rotationally fixed relative to the docking tube 202 and shaft once at least about 1%, about 2%, about 3%, about 4%, about 1% to about 5%, about 5% to about 10%, or about 10% to about 20% of the length of the handle 204 overlaps the docking tube 202. In some embodiments, the handle 204 forms a prismatic joint with the docking tube 202 and can only move linearly with respect to docking tube 202 (e.g., along a lengthwise direction). Thus, in some embodiments, handle 204 has only a single degree of freedom with respect to docking tube 202.
The end cap assembly 206 is shown in
The head 240 of the threaded insert 230 includes a chamfered annular surface 244 to engage the ring insert 232. The ring insert 232 also includes a corresponding chamfered annular surface 246 that engages the chamfered annular surface 244 of the threaded insert 230, thereby ensuring that the threaded insert 230, and consequently the docking tube 202, is centered within the elongated handle 204. The ring insert 232 is glued to a stepped opening 248 in the butt end of the underlisting 220 to provide a flat engagement surface 250 for the weighted end cap 234. The threaded insert 230 is optionally formed from aluminum, and the ring insert 232 is optionally a glass-filled polymer—for example, a glass-filled polyamide. The weighted end cap 234 is optionally the weighted end cap disclosed in U.S. Pat. No. 9,463,363, filed Mar. 3, 2015, the disclosure of which is hereby incorporated by reference in its entirety.
A distal end of the docking tube 202 may extend distally beyond a distal end of the elongated handle 204. The collar assembly 208 may be coupled to the distal end of one or more of the docking tube 202 and the elongated handle 204. One embodiment of the collar assembly 208 is shown in
The docking collar 254 may be optional, and, in some embodiments, the docking collar 254 is omitted and the docking sleeve 256 directly engages the lower end 258 of the docking tube 202. As shown in
The interchangeable golf club grip 200 can be attached to a straight or tapered golf club shaft in the following manner. The docking sleeve 256 is loosely inserted over a golf club shaft 270 as shown in
The golf club grip 200 is then press-fit onto the taped and wetted upper portion of the golf club shaft 270. As the golf club grip 200 is being press-fit onto the golf club shaft 270, the docking tube 202 engages the golf club shaft 270 and flexes outwardly as the widest portion of the golf club shaft 270 passes through the docking tube 202. Because the docking tube sidewall 212 is elastically deformable, it can accommodate various diameters, including the tapered outer diameter of a golf club shaft. Although described in relation to a tapered shaft, the docking tube 202 can instead be used in connection with straight (nontapered) shafts, if desired.
The docking tube 202 conforms to the outer diameter of the golf club shaft, and the elongated handle 204 is prevented from rotating relative to the docking tube 202. In some embodiments, the elongated handle 204 and docking tube 202 are coupled to the golf club shaft 270 simultaneously. In other embodiments, the docking tube 202 is coupled to the golf club shaft 270 and then the elongated handle 204 is coupled to the docking tube 202. Positioning the elongated handle 204 on the docking tube 202 may include positioning the projection in the channel such that the elongated handle 204 is rotationally fixed relative to the docking tube 202. Positioning the elongated handle 204 on the docking tube 202 may include moving the elongated handle 204 from a first position to a final position. The first position may be where the elongated handle 204 first engages the docking tube 202. The final position may be where the elongated handle 204 is fully positioned on the docking tube 202 and ready for use. The elongated handle 204 may be rotationally fixed relative to the docking tube 202 as the elongated handle 204 is moved from the initial position to the final position.
The weighted end cap 234 is inserted in the threaded insert 230 at the butt end of the golf club grip 200, and the docking sleeve 256 is brought into engagement with either the docking collar 254 or the exposed end of the docking tube 202.
The existing elongated handle 204 can be removed from the docking tube 202 and replaced with a different elongated handle 204. As shown in
The weighted end cap 234 is threaded into the threaded opening in the threaded insert 230, thereby centering the replacement handle 204′ on the docking tube 202 and preventing accidental retraction of the replacement handle 204′. The universal docking tube is adapted to fit over a wide variety of golf club shafts and is adapted to receive a wide variety of different-sized handles. For example, the golf club shafts can be straight, tapered, or stepped, and the golf club handles can be narrow, enlarged, pistol-shaped, cylindrical, or rectangular. The underlisting for each golf club handle provides a light interference fit over the universal docking tube and may fit over the universal docking tube in only a single orientation.
Referring to
A kit may include the docking tube 202 and at least one handle 204. The kit may include two handles 204 with the first handle having a different design than the second handle. For example, the first handle may be a first color and the second handle may be a second color different from the first color. The first handle may have a different dimension (e.g., length or diameter) than the second handle.
The above description is that of current embodiments of the invention. Various alterations and changes can be made without departing from the spirit and broader aspects of the invention as defined in the appended claims, which are to be interpreted in accordance with the principles of patent law, including the doctrine of equivalents. This disclosure is presented for illustrative purposes and should not be interpreted as an exhaustive description of all embodiments of the invention or to limit the scope of the claims to the specific elements illustrated or described in connection with these embodiments. The present invention is not limited to only those embodiments that include all of these features or that provide all of the stated benefits, except to the extent otherwise expressly set forth in the issued claims. Any reference to claim elements in the singular—for example, using the articles “a,” “an,” “the” or “said”—is not to be construed as limiting the element to the singular.
This application claims the benefit of U.S. patent application Ser. No. 17/396,147 filed Aug. 6, 2021, which claims the benefit of U.S. Provisional Patent Application No. 63/128,460 filed Dec. 21, 2020 and U.S. Provisional Patent Application No. 63/168,739 filed Mar. 31, 2021 entitled “Interchangeable Golf Club Grip with Shaft Attachment System”, each of which are incorporated by reference herein in their entirety.
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